U.S. patent number 10,132,188 [Application Number 14/755,223] was granted by the patent office on 2018-11-20 for axial turbomachine compressor inner shell.
This patent grant is currently assigned to SAFRAN AERO BOOSTERS SA. The grantee listed for this patent is Techspace Aero S.A.. Invention is credited to Stephane Hiernaux.
United States Patent |
10,132,188 |
Hiernaux |
November 20, 2018 |
Axial turbomachine compressor inner shell
Abstract
The present application relates to an axial turbomachine gaseous
flow-guiding element, such as a compressor inner shroud or vane.
The element includes a plasma generator including: a layer of
dielectric material with a guiding surface in contact with the
gaseous flow, a first electrode placed in the guiding surface, and
a second electrode electrically isolated from the first electrode
by means of the dielectric layer. The plasma generator drives the
gaseous flow along the guiding surface from the first electrode to
the second electrode and includes a third electrode covered by the
dielectric layer and electrically connected to the second
electrode, so as to participate in the generation of the plasma in
combination with the first electrode and the second electrode, the
second electrode being closer to the guiding surface than the third
electrode.
Inventors: |
Hiernaux; Stephane (Oupeye,
BE) |
Applicant: |
Name |
City |
State |
Country |
Type |
Techspace Aero S.A. |
Herstal (Milmort) |
N/A |
BE |
|
|
Assignee: |
SAFRAN AERO BOOSTERS SA
(Herstal (Milmort), BE)
|
Family
ID: |
51033014 |
Appl.
No.: |
14/755,223 |
Filed: |
June 30, 2015 |
Prior Publication Data
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Document
Identifier |
Publication Date |
|
US 20150377058 A1 |
Dec 31, 2015 |
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Foreign Application Priority Data
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Jun 30, 2014 [EP] |
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14174984 |
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Current U.S.
Class: |
1/1 |
Current CPC
Class: |
F02C
3/06 (20130101); F01D 9/041 (20130101); F01D
11/20 (20130101); F01D 9/04 (20130101); F01D
15/10 (20130101); F01D 5/145 (20130101); Y02T
50/60 (20130101); F05D 2270/172 (20130101); Y02T
50/673 (20130101); Y02T 50/672 (20130101) |
Current International
Class: |
F01D
15/10 (20060101); F01D 5/14 (20060101); F02C
3/06 (20060101); F01D 9/04 (20060101); F01D
11/20 (20060101) |
References Cited
[Referenced By]
U.S. Patent Documents
Foreign Patent Documents
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1995171 |
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Nov 2008 |
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EP |
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2008136697 |
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Nov 2008 |
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WO |
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2008136698 |
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Nov 2008 |
|
WO |
|
Other References
Search Report dated Dec. 2, 2014 from European Patent Appl. No.
14174984.6. cited by applicant.
|
Primary Examiner: Seabe; Justin
Assistant Examiner: Beebe; Joshua R
Attorney, Agent or Firm: Walton; James E.
Claims
I claim:
1. A guiding element of a gaseous flow of a turbomachine,
comprising: a plasma generator; a guiding surface of the gaseous
flow of the turbomachine; a layer of dielectric material in contact
with the gaseous flow of the turbomachine and partially forming the
guiding surface; a first electrode placed in the guiding surface; a
second electrode electrically isolated from the first electrode by
the dielectric layer, the plasma generator being configured so as
to drive the gaseous flow along the guiding surface from the first
electrode towards the second electrode by a driving plasma; and a
third electrode electrically connected to the second electrode so
as to participate in the generation of the driving plasma in
combination with the first electrode and the second electrode;
wherein the third electrode is covered by the dielectric layer and
the second electrode is closer to the guiding surface than the
third electrode, and the first electrode and the second electrode
partially forming the guiding surface and being biased at different
electric potentials.
2. The guiding element in accordance with claim 1, wherein the
dielectric layer comprises: a surface opposite the guiding surface
with respect to the thickness of the dielectric layer, the third
electrode being disposed on the opposite surface.
3. The guiding element in accordance with claim 1, wherein the
third electrode is disposed between the second electrode and the
first electrode in the flow direction of the gaseous flow.
4. The guiding element in accordance with claim 1, wherein the
gaseous flow is a primary annular flow of the turbomachine, the
first electrode being disposed upstream from the primary flow and
the second electrode being disposed downstream from the primary
flow.
5. The guiding element in accordance with claim 1, wherein the
second electrode and the third electrode are electrically isolated
from the gas flow and from the first electrode by the dielectric
layer.
6. The guiding element in accordance with claim 1, wherein the
second electrode is encased in the dielectric layer.
7. The guiding element in accordance with claim 1, wherein the
layer of dielectric material comprises: fibres so as to form a
composite material.
8. The guiding element in accordance with claim 1, wherein the
second electrode and the third electrode are connected together by
a conducting element and to the earth potential of the plasma
generator, the conducting element being a wire.
9. The guiding element in accordance with claim 1, being configured
to define an inner shroud comprising: outer annular surface for
guiding an annular flow; and an inner annular surface; wherein the
first electrode and the second electrode are disposed at the
downstream edge, the first electrode being in the inner surface,
and the second electrode being in the outer surface of the
shroud.
10. The guiding element in accordance with claim 1, being
configured to define a turbomachine vane, wherein the driving
plasma drives the flow in a circumferential direction toward the
vane.
11. An axial turbomachine compressor for compressing an annular
flow flowing axially therethrough, comprising: a rotor with several
rows of blades and a stator with several rows of vanes embracing
the blade rows, the stator comprising: a plasma generator; and at
least one of the vanes exhibiting a guiding surface of the annular
flow said guiding surface comprising a leading edge, a trailing
edge, a pressure face, and a suction face which extend from the
leading edge to the trailing edge, the plasma generator comprising:
a layer of dielectric material partially forming the guiding
surface in order to guide the compressed annular flow; a first
electrode placed in the guiding surface and partially forming the
guiding surface; a second electrode electrically isolated from the
first electrode by the dielectric layer, the plasma generator being
configured so as to drive the annular flow along the guiding
surface from the first electrode towards the second electrode by
means of a driving plasma; and a third electrode which is
electrically connected to the second electrode so as to participate
in the generation of the driving plasma in combination with the
first electrode and the second electrode; wherein the third
electrode is covered by the dielectric layer and the second
electrode is closer to the guiding surface than the third
electrode, wherein the first electrode and the second electrode
being arranged on the suction face of the vane and the third
electrode being disposed on the pressure side of the vane.
12. The axial turbomachine compressor in accordance with claim 11,
wherein the middle of the chord of the vane is disposed at the
first electrode.
13. The axial turbomachine compressor in accordance with claim 11,
wherein the second electrode forms the trailing edge of the vane,
and the vane comprises: a metal leading edge which is electrically
isolated from the first electrode, the second electrode and the
third electrode by the dielectric layer.
14. An axial turbomachine exhibiting a primary annular flow and a
secondary annular flow around the primary annular flow, the
turbomachine comprising: at least one shroud with a guiding surface
of the primary flow and which is formed of several segments
separated by separating gaps; and a plasma generator comprising: a
layer of dielectric material in contact with the primary flow of
the turbomachine and partially forming the guiding surface; a first
electrode placed in the guiding surface and partially forming the
guiding surface; a second electrode electrically isolated from the
first electrode by the dielectric layer, the plasma generator being
configured so as to drive the annular flow along the guiding
surface from the first electrode towards the second electrode by a
driving plasma; and a third electrode which is electrically
connected to the second electrode so as to participate in the
generation of the driving plasma in combination with the first
electrode and the second electrode, the driving plasma crossing
over the third electrode; wherein the third electrode is isolated
of the primary flow by the dielectric layer and the second
electrode is closer to the guiding surface than the third
electrode, and the first electrode and the second electrode being
disposed on either side of one of the separating gaps, the third
electrode passing through one of the separating gaps.
15. The axial turbomachine in accordance with claim 14, further
comprising: a power supply device for supplying power to the first
electrode in order to generate the driving plasma.
16. The axial turbomachine in accordance with claim 14, wherein the
shroud includes an upstream edge and a downstream edge, the first
electrode being disposed at the upstream edge and the second
electrode being disposed at the downstream edge.
17. The axial turbomachine in accordance with claim 14, wherein the
guiding surface is an outer guiding surface, the first electrode
and the second electrode are disposed on the outer guiding surface
of the shroud.
18. The axial turbomachine in accordance with claim 14, wherein at
least one of the first electrode, the second electrode and the
third electrode is axially facing the rotor.
Description
This application claims priority under 35 U.S.C. .sctn. 119 to
European Patent Application No. 14174984.6, filed 30 Jun. 2014,
titled "Axial Turbomachine Compressor Inner Shell," which is
incorporated herein by reference for all purposes.
BACKGROUND
1. Field of the Application
The present application relates to the field of electric barrier
discharge plasma generators for turbomachines. The present
application more specifically relates to a turbomachine
flow-guiding element comprising a plasma generator for driving a
flow along a surface, possibly in order to avoid flow separations.
The present application also relates to a turbomachine comprising
an electric barrier discharge plasma generation system.
2. Description of Related Art
An aircraft turbojet engine generally comprises a fan, a
compressor, a combustion chamber, and a turbine. In operation, the
flows in the modules may encounter instabilities, such as surge
phenomena. These instabilities limit the turbojet's possibilities,
and can degrade performance.
In order to overcome these drawbacks, it is known to use an
electrical discharge plasma generator with dielectric barrier that
is integrated into a guiding surface of a casing. Such a generator
can drive air near the casing, along its guiding surface.
Document US 2010/0040453 A1 discloses a turbomachine for an
aircraft comprising an outer casing provided with a plasma
generator. The plasma generator comprises a layer of dielectric
material, a first electrode exposed to the flow of the
turbomachine, and a second electrode surrounded by the dielectric
layer so as to isolate the first electrode. The plasma generator is
designed to drive air along the casing, and to increase the flow in
the corresponding stream. The limits of the turbomachine are pushed
back by controlling instabilities that may occur during operation.
However, such a generator requires a significant amount of energy,
and the amount of plasma created remains small. Managing
instabilities thus requires an amount of energy that penalises the
overall efficiency of the turbomachine. The plasma is
heterogeneous.
Although great strides have been made in the area of flow-guiding
elements in axial turbomachine compressors, many shortcomings
remain.
DESCRIPTION OF THE DRAWINGS
FIG. 1 represents an axial turbomachine according to the present
application.
FIG. 2 is a diagram of a turbomachine compressor according to the
present application.
FIG. 3 illustrates a guiding element, such an inner shroud,
according to a first embodiment of the present application.
FIG. 4 illustrates a guiding element, such an inner shroud,
according to a second embodiment of the present application.
FIG. 5 illustrates a guiding element, such an inner shroud,
according to a third embodiment of the present application.
FIG. 6 illustrates a guiding element, such a vane, according to a
fourth embodiment of the present application.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
The present application aims to solve at least one of the problems
of the prior art. More particularly, the present application aims
to improve the overall efficiency of a turbomachine comprising a
plasma generator. The present application also aims to improve the
stability of a flow in a turbomachine comprising a flow-guiding
element equipped with a plasma generator. The present application
also aims to reduce the surge phenomena in a turbomachine
comprising a flow-guiding element equipped with a plasma
generator.
The present application relates to a turbomachine gaseous
flow-guiding element, notably a compressor, the element comprising
a plasma generator with a layer of dielectric material with a
guiding surface in contact with the gaseous flow of the
turbomachine, a first electrode placed in the guiding surface, a
second electrode electrically isolated from the first electrode by
means of the dielectric layer, the plasma generator being
configured so as to drive the gaseous flow along the guiding
surface from the first electrode to the second electrode,
remarkable in that the plasma generator further comprises a third
electrode covered by the dielectric layer and electrically
connected to the second electrode so as to participate in the
generation of the plasma in combination with the first electrode
and the second electrode, the second electrode being closer to the
guiding surface than the third electrode.
According to an advantageous embodiment of the present application,
the dielectric layer comprises a surface opposite the guiding
surface depending on the thickness of the dielectric layer, the
third electrode being disposed on said opposite face, preferably
the guiding surface and the opposite surface are main surfaces of
the dielectric layer.
According to an advantageous embodiment of the present application,
the third electrode is disposed between the second electrode and
the first electrode in the direction of the gaseous stream,
preferably the third electrode is disposed in the middle between
the first electrode and the second electrode according to the
direction of the gaseous stream.
According to an advantageous embodiment of the present application,
the gaseous flow is an annular primary flow of the turbomachine,
the first electrode being disposed upstream from the primary flow
and the second electrode being disposed downstream from the primary
flow, optionally the electrodes occupy the majority of the length
of the element.
According to an advantageous embodiment of the present application,
the second electrode and the third electrode are electrically
isolated from the gaseous stream and/or the first electrode owing
to the dielectric layer, preferably the second electrode is encased
in the dielectric layer or covered with a dielectric coating.
According to an advantageous embodiment of the present application,
the layer of dielectric material comprises fibres so as to form a
composite material, optionally at least one or each electrode is in
contact with glass fibres.
According to an advantageous embodiment of the present application,
the second electrode and the third electrode are connected to an
earth of the plasma generator, preferably the second electrode and
the third electrode are electrically connected in parallel.
According to an advantageous embodiment of the present application,
the element is a turbomachine shroud, the shroud comprises an
upstream edge and a downstream edge, optionally the first electrode
is disposed at the upstream edge and the second electrode is
disposed at the downstream edge.
According to an advantageous embodiment of the present application,
the shroud is formed of several segments separated by separating
gaps, the first electrode and the second electrode being disposed
on either side of one of the separating gaps, the third electrode
crossing one of the separating gaps.
According to an advantageous embodiment of the present application,
the shroud is an inner shroud and there guiding surface is an
external guiding surface, the first electrode and the second
electrode being disposed on the outer guiding surface of the
shroud.
According to an advantageous embodiment of the present application,
the shroud is an inner shroud which comprises an outer annular
surface designed to guide an annular flow, and an inner annular
surface, the first electrode and the second electrode being
disposed at the downstream edge, the first electrode being on the
side of the inner surface, and the second electrode being on the
side of the outer surface of the shroud.
According to an advantageous embodiment of the present application,
the element is a turbomachine vane, possibly a compressor stator
vane, the vane comprising a leading edge, a trailing edge, a
pressure face and a suction face extending from the leading edge to
the trailing edge, the first electrode and the second electrode are
disposed on the suction face of the vane and the third electrode is
disposed on the pressure face of the vane.
According to an advantageous embodiment of the present application,
the middle of the chord of the vane is disposed at the first
electrode.
According to an advantageous embodiment of the present application,
the second electrode forms the trailing edge, preferentially the
vane comprises a metal leading edge that is electrically isolated
from the electrodes by means of a dielectric layer.
According to an advantageous embodiment of the present application,
the first electrode and the second electrode are offset relative to
each other along the entire length of the strip.
According to an advantageous embodiment of the present application,
the dielectric layer may comprise a stack of several layers of
dielectric material.
According to an advantageous embodiment of the present application,
the electrodes are connected to a voltage generator.
According to an advantageous embodiment of the present application,
the voltage generator is connected to earth.
According to an advantageous embodiment of the present application,
the electrodes are generally parallel.
According to an advantageous embodiment of the present application,
the first electrode and the second electrode are integrated in the
thickness of the element and flush with its outer surface.
According to an advantageous embodiment of the present application,
the electrodes are integrated in the thickness of the layer of
dielectric material.
According to an advantageous embodiment of the present application,
the first electrode is generally planar and in contact with the
gaseous stream, the second electrode and the third electrode being
offset relative to the general plane of the first electrode.
According to an advantageous embodiment of the present application,
the shroud is a shroud for an axial turbomachine, the axial centre
of the shroud being at the axial level of the third electrode.
According to an advantageous embodiment of the present application,
the plasma generator comprises a conductive member connecting the
second electrode to the third electrode.
The present application also relates to a turbomachine comprising
at least one gaseous flow-guiding element, characterised in that
the element is in compliance with the present application,
preferably the turbomachine comprises a device for supplying power
to each first element, and/or a battery to supply power to each
first element, the battery being optionally connected to the power
supply device of the turbomachine.
According to an advantageous embodiment of the present application,
at least one of the electrodes radially faces the rotor.
According to an advantageous embodiment of the present application,
the driving plasma drives the flow toward the rotation axis of the
compressor or of the turbomachine.
According to an advantageous embodiment of the present application,
the turbomachine is a turbo reactor, preferably of a plane.
The electrodes also allow the guiding element to be mechanically
reinforced. The plasma is more homogeneous. It is obtained with
less energy and further accelerates the stream. The margin of
stability of the turbomachine is increased, and secondary losses
are limited.
As described herein, the terms internal or interior and external or
exterior refer to a position in relation to the axis of rotation of
an axial turbomachine.
FIG. 1 schematically shows an axial turbomachine. In this case, it
is a double-flow turbojet engine. The turbojet engine 2 comprises a
first compression level, designated low-pressure compressor 4, a
second compression level, designated high pressure compressor 6, a
combustion chamber 8 and one or more turbine levels 10. In
operation, the mechanical power transmitted to the turbine 10 via
the central shaft to the rotor 12 moves the two compressors 4 and
6. Each of the various turbine levels can be connected to the
compressor stages via concentric shafts. The latter comprise
several rows of rotor blades associated with rows of stator vanes.
The rotation of the rotor about its axis of rotation 14 thus
generates a flow of air and gradually compresses the latter up to
the inlet of the combustion chamber 8.
An intake fan 16 is coupled to the rotor 12 and generates an air
flow which is divided into a primary flow 18 passing through the
various abovementioned levels of the turbomachine, and a secondary
flow 20 passing through an annular conduit (shown in part) along
the machine that then joins the primary flow at the turbine outlet.
The secondary flow can be accelerated so as to generate a reaction.
The primary flow 18 and secondary flow 20 are annular flows; they
are guided by the casing of the turbomachine. For this purpose, the
casing has cylindrical walls or shrouds which may be internal and
external to guide the interior or exterior of an annular flow.
FIG. 2 is a sectional view of a compressor of an axial turbomachine
2 such as that of FIG. 1. The compressor may be a low-pressure
compressor 4. One can observe a portion of the fan 16 and the
separator nose 22 of the primary flow 18 and the secondary flow 20.
The rotor 12 comprises several rows of rotor blades 24, in this
case three.
The low-pressure compressor 4 comprises a plurality of rectifiers,
in this case four, each of which contain a row of stator vanes 26.
The rectifiers are associated with the fan 16 or a row of rotor
blades for rectifying the airflow, so as to convert the flow
velocity into pressure.
The stator vanes 26 extend substantially radially from an exterior
casing, and can be secured by means of a pin. The stator vanes are
evenly spaced, and have the same angular orientation in the flow.
Advantageously, the vanes of the same row are identical.
Optionally, the spacing between the vanes can vary locally as well
as their angular orientation. Some vanes may be different from the
rest of the vanes of their row, for example by the presence or
configuration of plasma generators.
The inner ends of the stator vanes 26 can support an inner shroud
28. Each inner shroud 28 is circular in shape, and can be
segmented. At least one or each inner shroud may be formed of
angular segments. At least one or each inner shroud 28 can be used
to mechanically connect several stator vanes 26 of the same row.
Each inner shroud can be used to guide and/or to define the primary
flow 18.
At least one or each inner shroud 28 may comprise a sealing layer,
such as an abradable layer 30 or brittle layer. Each abradable
layer 30 can be designed to cooperate with rubbing fins, or annular
ribs formed on the external surface of the rotor 12 to ensure
sealing. Each abradable layer 30 may be silicone-based. The
combination of brush seals and an abradable layer limits the
recirculation of fluid that is reinjected upstream from the inner
shroud passing along the rotor 12.
FIG. 3 shows a flow-guiding element, such as a turbomachine shroud
28, possibly internal. The shroud 28 may be that of a low-pressure
compressor, for example, such as that shown in FIG. 2. The shroud
may be a high-pressure compressor shroud, or a turbine shroud.
The shroud 28 or each shroud may comprise at least one plasma
generator, which may comprise a layer of dielectric material 32, a
first electrode 34, a second electrode 36, a third electrode 38,
and a voltage generator 40 connected to at least one of the
electrodes. The plasma generator may include an earth 42. A voltage
generator may be common to a plurality of plasma generators which
are disposed at various locations on the shroud, and/or a plurality
of shrouds, and/or at several locations on the turbomachine. The,
or each, plasma generator is configured to ionize a part of the
gas, and to drive the ions formed by means of an electric field.
The entrained ions in turn drive part of the gaseous flow 44 along
the guiding surface 46 from upstream to downstream.
The dielectric layer 32 may have an annular shape, and optionally
form an annular body. It may form the majority of the radial
thickness of the inner shroud 28 and/or the entire axial length of
the shroud 28. It can mechanically interconnect several stator
vanes. It can comprise several cavities 48 or pockets 48 in which
the vane ends are secured.
The dielectric layer 32 can be a material that electrically
isolates the electrodes (34; 36; 38) from one other. This layer may
include glass, polymeric materials such as the epoxy resin,
polypropylene, polyethylene, Teflon or a combination of these
materials. It may be a composite material, with a fibre-reinforced
resin. The resin can be a polymer material such as those mentioned
above; the fibres can be glass. The dielectric layer 32 can include
a guiding surface 46 of the gaseous flux flowing through the
turbomachine, and it may be the outer surface of the shroud 28
which defines the inside of the primary flow. The dielectric layer
32 may be formed of several layers of dielectric material. The
dielectric layer 32 may include, according to its radial thickness,
a surface 50 opposite the guiding surface 46. Said surfaces may be
major surfaces, which are so considered by their sizes.
At least one or each electrode (34; 36; 38) may be circular and
extend around the periphery of the shroud 28. They may be metallic.
Alternately, at least one, or some, or all the electrodes (34; 36;
38) can be segmented, in order to be placed, for example, between
the stator vanes, by being distributed around the shroud 28.
According to the revolution profile of the shroud, the electrodes
(34; 36; 38) can be generally parallel to each other. The first 34,
the second 36 and the third electrodes 38 can be offset axially
and/or radially from one another. In combination, they can extend
over the axial majority of the shroud 28.
The first electrode 34 may be disposed upstream from the inner
shroud 28. It can be disposed in the upstream half of the shroud,
optionally at the upstream edge 52. Optionally, it is directly
connected to the voltage generator 40. It can be placed in the
guiding surface 46; i.e., it can be surrounded by the guiding
surface 46, and/or to be incorporated in it by forming surface
continuity. The surface of the first electrode 34 may be in contact
with the primary flow of the turbomachine. Said surface may be
flush with the guiding surface.
The second electrode 36 is electrically isolated from the first
electrode owing to the dielectric layer 32. Electrical isolation
can be understood as a physical separation still enabling the
creation of a plasma. The second electrode 36 can be encased by the
dielectric layer 32. It can be set back from the guiding surface
46. It can be covered on one face by the dielectric layer 32 and be
coated with an insulator on the other face, for example with
dielectric material. It can be connected to the voltage generator
40 on the terminal opposite that on which the first electrode 34 is
connected. It can be connected to the earth 42. The second
electrode 36 is disposed downstream from the first electrode 34,
for example in the downstream half of the shroud 28, optionally
axially from the downstream edge 54 of the shroud.
The third electrode 38 is covered by the dielectric layer 32 so as
to be electrically isolated from the first electrode 34 and from
the second electrode 36. It can be disposed on the opposite surface
50 of the dielectric layer. It can be further away from the guiding
surface than is the second electrode 36. It is disposed axially
between the first electrode 34 and the second electrode 36. The
third electrode 38 may be connected to the second electrode 36,
possibly directly through a conductive member, or via the common
earth 42 of the electrical circuit of the plasma generator. It can
be connected to the voltage generator 40 and/or to the earth 42 in
the same manner as the second electrode 36.
The abradable layer 30 can cover the third electrode 38, and
optionally encapsulate it in combination with the dielectric layer
32. The dielectric layer 32 may form an electrical barrier between
the first electrode 34 on the one hand, and the second and third
electrodes.
With the arrangement described above, the electrodes (34; 36; 38)
make it possible to generate a plasma in combination.
FIG. 4 illustrates a guiding element 128 according to a second
embodiment of the present application. This FIG. 4 reflects the
numbering of the previous figures for identical or similar
elements, although the numbering is incremented from 100. Specific
numbers are used for elements specific to this embodiment.
The shroud 128 essentially differs from the first embodiment in
that the first electrode 134 is disposed at the downstream edge 154
of the shroud, on the inner surface of the dielectric layer 132.
One of the faces of the first electrode 134 may be covered,
possibly for the most part, by the abradable layer 130. The guiding
surface 146 is thus the downstream surface of the shroud. A portion
of the first electrode 134 may be defined by the abradable layer
130 and the dielectric layer 132. This plasma generator
architecture allows it to resist flow recirculations under the
shroud. The plasma generator can then be configured so as to
generate a gas flow 144 circulating radially outwardly.
FIG. 5 illustrates a guiding element according to a third
embodiment of the present application. This FIG. 5 reflects the
numbering of the previous figures for identical or similar
elements, although the numbering is incremented from 200. Specific
numbers are used for elements specific to this embodiment.
The shroud 226 can be segmented. It may have open gaps 256 that
form angular separations between the segments. It can also have
pockets 248 or apertures for introducing and securing the ends of
vanes 226.
The third electrode 238 is disposed across a gap 256 between
neighboring shroud segments. It may extend onto the two shroud
segments 228 on either side of the gap 256. The first electrode 234
is disposed on one side of the gap 256, and the second electrode
236 is disposed on the other side of the gap 256, the first
electrode 234 and second electrode 236 being arranged on the same
radial face of the shroud 228, for example on the outer surface. At
least one electrode, for example the first electrode 234, can be
arranged in the vane root, for example in a vane mounting pocket
248.
This configuration generates plasma that can span a separating gap
256. This plasma can result in a flow 246 or stream along the outer
surface of the shroud, depending on its circumference, preventing
the stream from being engulfed in the gap.
FIG. 6 illustrates a guiding element according to a fourth
embodiment of the present application. This FIG. 6 reflects the
numbering of the previous figures for identical or similar
elements, although the numbering is incremented from 300. Specific
numbers are used for elements specific to this embodiment.
The guide element is a vane 326, such as a stator vane. It is
obvious to those skilled in the art that the present application
can equally be applied to a rotor blade or to a fan blade. The vane
326 comprises a vane adapted to extend into the flow of the
turbomachine, the vane having a leading edge 358, a trailing edge
360, a pressure face 362 and a suction face 364, said surfaces
extending from the leading edge 358 to the trailing edge 360. The
vane is mainly formed by the layer of dielectric material 332. The
dielectric material 332 is advantageously a composite material so
as to optimise the mechanical strength. The dielectric layer shows
a half pressure face and a half suction face.
The vane of the vane 326 has a curved airfoil and a chord. The
first electrode 334 is disposed on the suction face 364, for
example in the middle of the chord of vane 326, or in the middle,
axially, of the vane. The trailing edge 360 may be formed by the
second electrode 336 which is separated and/or electrically
isolated from the first electrode 334 by the dielectric layer 334.
The third electrode 338 is disposed on the surface 350 opposite to
the suction face 364, i.e. on the pressure face 362. The first
electrode 334 may be housed in the thickness of the suction face
half, and the third electrode 338 may be housed in the thickness of
the pressure face half. Optionally, the second electrode has a
thickness substantially equal to the thickness of the downstream
part of the dielectric layer 332. The third electrode 338 may then
further from the suction face 364 than the second electrode 336. It
can be disposed axially between the first and the second electrode,
optionally in the middle.
Each of the electrodes (334; 336; 338) can extend over the majority
of the radial height of the vane of the vane 326, optionally over
its entire radial height. The vane 326 may comprise a metal leading
edge 358 which could be an electrode. This leading edge can be
isolated from other electrodes by means of a dielectric layer 332.
In this configuration, the vane is completely formed by the plasma
generator, except possibly its leading edge.
With the present configuration, the plasma generator is used to
drive the flow 344 along the suction face 364 of the vane 326. More
flow 344 thus follows the airfoil of the vane. The latter becomes
more efficient in guiding and/or deflecting, and/or accelerating
the flow.
All embodiments of the present application can be combined on the
same rectifier, on the same shroud, on a turbomachine. The
description above deals with a trio of electrodes forming a plasma
generator. The scope of the present application also relates to
vanes, shrouds, and turbomachines each having one or more
electrodes trios, each forming a plasma generator. One or each or
several trios of electrodes are in accordance with the description
above.
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